KR20230164301A - Drywall stud with improved sound insulation performance - Google Patents

Abstract

A stud for drywall that can further improve sound insulation performance is disclosed. According to the present invention, it relates to a stud that has a predetermined cross-section and extends in the longitudinal direction to provide a support structure for drywall, comprising: an inner and outer connection portion; An inner transverse extension portion extending from one end of the inner and outer connection portion and fastened to the drywall on one side; and an outer transverse extension portion extending from an end opposite the inner and outer connection portion and fastened to the drywall on the opposite side; wherein the inner and outer transverse extension portions include a part or all of an elastic material and are bent at least one way. A stud for drywall is provided that has a portion and is partially installed in contact with each drywall. The present invention can reduce sound pressure transmission through studs and improve the sound insulation performance of drywall by reducing the contact area with the outer surface of drywall and dissipating acoustic energy through bent parts.

Description

Stud for drywall with improved sound insulation performance {DRYWALL STUD WITH IMPROVED SOUND INSULATION PERFORMANCE}

The present invention relates to studs that can be used in drywall for various structures.

Drywall is known as one of the construction methods for forming the walls of structures. The demand for drywall is continuously increasing because the construction period is significantly shorter and construction is simpler than wet wall, which requires pouring concrete into a formwork and curing it, and the scope of application is also expanding. Typically, drywall is widely used in boundary walls between households in prefabricated houses or apartment complexes, and drywall is also used in commercial buildings such as offices, hotels, and movie theaters to partition or separate spaces.

Drywall may be composed of upper and lower runners installed horizontally and a plurality of studs installed vertically between the upper and lower runners. In addition, finishing materials are installed on the front and back of the runner and studs, and insulation, absorbing materials, air layers, etc. are installed in the internal space between the drywall to form a wall. Gypsum board is a representative finishing material, but steel fiber reinforced panels, extruded concrete panels, and ALC (Autoclaved Lightweight Concrete) panels are also used depending on the structural type of the structure.

The structure of drywall and the studs used therein have been known in various ways and forms. For example, “Steel Stud Structure and Dry Wall System Equipped with the Same” of Registered Patent No. 10-1500456 proposes a method to more easily improve the installation of electrical equipment or piping, and “Steel Stud Structure and Dried Wall System Equipped with the Same” of Registered Patent No. 10-1500456 proposes a way to more easily improve the installation of electrical equipment or piping. “One-touch fastening structure for drywall studs” proposes a method for fastening studs to runners in drywall without fastening bolts. In addition, Registered Patent No. 10-0655890, “Dry wall system using panel-type studs and its construction method,” proposed a method of improving work efficiency in the field by installing panel-type studs in conjunction.

However, despite many improvements to date, drywall still has room for improvement. One of them is the improvement of sound insulation performance in drywall, especially drywall using gypsum board. The sound insulation performance of drywall is also related to the studs installed between the front and rear finishing materials, and sound pressure generated from the outside is transmitted to the drywall (exterior), studs, and drywall (inside) and flows into the room. Accordingly, there is a demand for a type of stud that can further improve sound insulation performance.

Registered Patent No. 10-1500456 (registered on March 3, 2015) Registered Patent No. 10-1190249 (registered on October 5, 2012) Registered Patent No. 10-0655890 (registered on December 4, 2006)

Embodiments of the present invention seek to provide studs for drywall that can further improve sound insulation performance.

Additionally, embodiments of the present invention seek to provide studs for drywall that can reduce the transmission of sound pressure by consuming acoustic energy through the studs.

In addition, embodiments of the present invention seek to provide drywall studs that have the above-mentioned sound insulation performance improvement and sound energy consumption effects, are relatively easy to manufacture or process, and can maintain constructability at a similar level to the existing one. .

However, the technical problems to be achieved by the embodiments of the present invention are not necessarily limited to the technical problems mentioned above. Other technical problems not mentioned can be clearly understood by those skilled in the art from the detailed description and other descriptions in the specification.

According to one aspect of the present invention, it relates to a stud that has a predetermined cross-section and extends in the longitudinal direction to provide a support structure for drywall, comprising: an inner and outer connection portion; an inner transverse extension portion extending from one end of the inner and outer connection portion and fastened to a dry wall on one side; and an outer transverse extension portion extending from an end opposite the inner and outer connection portion and fastened to the drywall on the opposite side, wherein the inner and outer transverse extension portions include an elastic material in part or all, and one A stud for drywall may be provided that has the above bent portion and is partially installed in contact with each drywall.

Studs for drywall according to embodiments of the present invention reduce the contact area with the outer surface of the drywall and dissipate acoustic energy through the bent portion, thereby reducing sound pressure transmission through the stud and improving the sound insulation performance of the drywall. can do.

In addition, despite the above advantages, drywall studs according to embodiments of the present invention can be manufactured or processed relatively easily by adding only a predetermined bent shape to the existing stud shape. In addition, the left and right widths of the studs can be easily manufactured to the same or corresponding specifications as existing studs, so compatibility with existing construction structures and constructability can also be maintained.

However, the technical effects that can be achieved through embodiments of the present invention are not necessarily limited to the effects mentioned above. Other technical effects that are not mentioned can be clearly understood by those skilled in the art from the detailed description and other descriptions in the specification.

Figure 1 is a diagram schematically showing a typical conventional drywall structure.
Figure 2 is an enlarged view of the studs and drywall shown in Figure 1.
Figure 3 is a diagram schematically showing a stud for drywall according to the first embodiment of the present invention.
Figure 4 is a diagram schematically showing the construction of the drywall stud shown in Figure 3.
Figure 5 is a diagram schematically showing a stud for drywall according to a second embodiment of the present invention.
Figure 6 is a diagram schematically showing a stud for drywall according to a third embodiment of the present invention.
Figure 7 is a diagram schematically showing a stud for drywall according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. The following examples may be provided to more completely explain the present invention to those skilled in the art. However, the following examples are provided to aid understanding of the present invention, and the technical idea of the present invention is not necessarily limited to the following examples. In addition, detailed descriptions will be omitted for those that obscure the technical gist of the present invention or for known configurations.

Figure 1 is a diagram schematically showing a typical conventional drywall structure. Figure 2 is an enlarged view of the studs and drywall shown in Figure 1.

Referring to Figures 1 and 2, a conventional drywall structure may include an upper runner 30 installed horizontally and a lower runner 30 installed horizontally from the lower side to correspond thereto. Additionally, a plurality of studs 10 may be installed between the upper and lower runners 30. The studs 10 may be installed in a vertical direction so as to be approximately perpendicular to the runner 30, and a plurality of studs 10 may be installed spaced apart along the longitudinal direction of the runner 30.

Meanwhile, drywall 20 can be installed inside and outside the frame formed by the studs 10 and runners 30, thereby forming a single drywall structure. Drywall 20 may typically include gypsum board. For reference, in FIGS. 1 and 2, for convenience of illustration, only the dry wall 20 on one side (outer side) is shown, and the opposite side (inner side) is omitted.

The stud 10 may be fastened to the drywall 20 to provide a support structure for the drywall 20. Specifically, the stud 10 has an approximately "ㄷ"-shaped cross section including an inner transverse extension part 11, an outer transverse extension part 12, and an inner and outer connection part 13, and can be formed to extend up and down. The outer transverse extension 12 may be fastened to the drywall 20 on one side (outside), and the inner transverse extension 11 may be fastened to the drywall 20 on the opposite side (inside). The space between the inner and outer transverse extensions 11 and 12 and the drywall 20 can be fixed through anchors, pieces, screws, etc.

The conventional stud 10 as described above can be in close contact with the drywall 20 throughout the width direction of the inner and outer lateral extension parts 11 and 12. The inner and outer transverse extensions 11 and 12 may have a width of about 40 to 60 mm on the left and right, and usually have a width of about 50 mm. Therefore, the sound pressure transmitted from the outside is transmitted to the outer transverse extension part 12 in an area of about 50 mm through the dry wall 20, and then passes through the inner and outer connection part 13 and the inner transverse extension part 11 to reach the interior. may flow into. Since these conventional studs (10) were designed with the main purpose of supporting the drywall (20), the inner and outer transverse extensions (11, 12) are firmly attached to each drywall (20). It is fixedly installed, and as a result, it is vulnerable to noise entering the room through the stud 10.

Figure 3 is a diagram schematically showing a stud for drywall according to the first embodiment of the present invention.

Referring to FIG. 3, a drywall stud 100 (hereinafter referred to as stud 100) according to this embodiment may have a predetermined cross-sectional shape and extend vertically.

Specifically, the stud 100 of this embodiment may be provided with an inner transverse extension part 110, an inner and outer connection part 130, and an outer transverse extension part 120. The inner transverse extension portion 110, the inner and outer connecting portion 130, and the outer transverse extension portion 120 may form a predetermined cross-sectional shape and extend up and down. In the stud 100 of this embodiment, the inner transverse extension portion 110, the inner and outer connection portion 130, and the outer transverse extension portion 120 are illustrated as having a generally modified “ㄷ” shaped cross-sectional shape. there is.

The inner transverse extension portion 110, the inner and outer connection portion 130, and the outer transverse extension portion 120 may be formed as one member. In other words, the inner transverse extension portion 110, the inner and outer connecting portion 130, and the outer transverse extension portion 120 may be formed by bending a substantially planar member into a predetermined cross-sectional shape. This has advantages in terms of processing costs and productivity.

Additionally, the inner transverse extension portion 110, the inner and outer connecting portion 130, and the outer transverse extension portion 120 may be partially or entirely made of an elastic material. Preferably, the inner transverse extension portion 110, the inner and outer connecting portion 130, and the outer transverse extension portion 120 may be formed by bending one elastic member into a predetermined cross-sectional shape.

Looking at each part in more detail, first, the stud 100 of this embodiment may include an inner and outer connection portion 130.

The inner and outer connecting portions 130 may have a predetermined width in the inner and outer directions. Additionally, the inner and outer connecting portions 130 may have the above width and extend in the vertical direction. In this embodiment, the inner and outer connection portions 130 are illustrated in the form of a flat plate with a predetermined width.

Meanwhile, the stud 100 of this embodiment may include an inner transverse extension portion 110.

The inner transverse extension portion 110 may be formed by bending from one end of the inner and outer connecting portion 130 to correspond to the left and right directions. The inner transverse extension portion 110 is generally extended to correspond to the left and right directions and may be arranged to be approximately perpendicular to the inner and outer connection portions 130.

The inner transverse extension portion 110 is disposed toward the inside of a predetermined space and can be fastened to the dry wall 20 facing inward. The connection between the inner transverse extension 110 and the drywall 20 can be achieved by various known methods, and the connection method is not particularly limited. For example, the inner transverse extension 110 may be fastened to the drywall 20 through anchors, pieces, screws, etc.

Looking at the structure of the inner transverse extension portion 110 in more detail, first, the inner transverse extension portion 110 may be provided with a first horizontal extension portion 111. The first horizontal extension portion 111 may be bent to correspond to the left and right directions from one end of the inner and outer connecting portion 130 to extend a predetermined width. The first horizontal extension portion 111 may be substantially perpendicular to the inner/outer connecting portion 130 or may extend in a direction substantially parallel to the left and right directions.

Additionally, the inner transverse extension 110 may include a first inclined extension 112. The first inclined extension portion 112 extends from one end of the first horizontal extension portion 111, and may be formed to extend inclined at a predetermined angle with respect to the left and right directions so as to gradually approach the inner drywall 20. For example, the first inclined extension portion 112 may have an inclination angle of 10 to 30 degrees in the left and right directions and may extend from an end of the first horizontal extension portion 111. This first inclined extension 112, together with the second inclined extension 114, which will be described later, contributes to reducing the contact area between the drywall 20 and the stud 100.

Meanwhile, the inner transverse extension 110 may include a second horizontal extension 113. The second horizontal extension portion 113 extends from one end of the first inclined extension portion 112, and may be formed to extend substantially in the left and right directions, similar to the first horizontal extension portion 111. Additionally, the second horizontal extension portion 113 may contact the outer surface of the dry wall 20 and be coupled to the dry wall 20. This is in contrast to the case where the above-described first horizontal extension portion 111 and first inclined extension portion 112 do not directly contact the drywall 20 but are spaced apart from each other at a predetermined interval. The drywall 20 can be contacted and coupled to the second horizontal extension portion 113 in this way and supported on the inner transverse extension portion 110.

Additionally, the second horizontal extension portion 113 may be provided with a contact support surface 113a on one surface facing the dry wall 20. The contact support surface 113a may be defined as one surface (a surface facing inward) of the second horizontal extension 113 that is directly contacted and coupled to the outer surface of the drywall 20.

Meanwhile, the inner transverse extension 110 may include a second inclined extension 114. The second inclined extension portion 114 extends from one end of the second horizontal extension portion 113 and may be formed to extend inclined at a predetermined angle with respect to the left and right directions so as to gradually move away from the outer surface of the drywall 20. The second inclined extension 114 is generally formed in a symmetrical shape with the above-described first inclined extension 112, and may have an inclination angle or width corresponding to the first inclined extension 112.

Additionally, the inner transverse extension 110 may include a third horizontal extension 115. The third horizontal extension 115 extends from one end of the second inclined extension 114, and may be formed to extend substantially in the left and right directions, similar to the first horizontal extension 111. The third horizontal extension 115 is generally formed in a symmetrical shape with the above-described first horizontal extension 111, and may have a direction or width corresponding to the third horizontal extension 115.

The inner transverse extension 110 as described above is in direct contact with the drywall 20 only in the area of the second horizontal extension 113, and can be installed to be spaced apart from the drywall 20 by a predetermined distance in the remaining area. there is. Accordingly, the contact area between the drywall 20 and the stud 100, that is, the inner transverse extension 110, can be reduced, and as the contact area is reduced, the transmission of sound pressure through the stud 100 is also reduced. It may decrease. In other words, sound insulation performance can be improved.

In addition, the bent portions caused by the first and second inclined extension parts 112 and 114 can also function as an elastic body that dissipates acoustic energy (vibration) transmitted through the stud 100. This can contribute significantly to improving the sound insulation performance of the drywall 20 along with minimizing the contact surface mentioned above.

Meanwhile, the overall left and right width W1 of the inner transverse extension 110 may be generally similar to the width of the conventional stud 10. For example, the total left and right width W1 of the inner transverse extension 110 may be approximately 40 to 60 mm, and more typically, approximately 50 mm. The stud 100 of the present embodiment has a total left and right width W1 similar to that of the prior art, and reduces the area in direct contact with the drywall 20 (i.e., the second horizontal extension 113) through a bent shape. , effects such as improved sound insulation performance can be achieved. Alternatively, this has advantages in terms of ensuring compatibility with existing construction structures and convenience of manufacturing and processing.

In addition, the left and right widths W2 of the second horizontal extension 113 need to be set to an appropriate width so as to reduce the direct contact area with the dry wall 20 and maintain a stable bonding force with the dry wall 20. . For example, the left and right widths (W2) of the second horizontal extension portion 113 may be 30 to 60% of the total left and right widths (W1) of the inner transverse extension portion 110.

Meanwhile, the stud 100 of this embodiment may include an outer transverse extension portion 120.

The outer transverse extension portion 120 may be provided at an end opposite to the inner and outer connection portion 130 to correspond to the inner transverse extension portion 110. The outer transverse extension portion 120 may be bent and extended from the opposite end of the inner and outer connecting portion 130 to generally correspond to the left and right directions, and is disposed toward the outside of the defined space, forming the outer drywall 20. ) can be concluded with.

The outer transverse extension portion 120 may be formed substantially similar to the inner transverse extension portion 110 described above. In the case of this embodiment, the outer transverse extension portion 120 is illustrated as having a generally symmetrical structure or shape with the inner transverse extension portion 110. This outer transverse extension 120 is formed by bending and extending from the opposite end of the inner and outer connecting portion 130, and the outer drywall (121) is formed from one end of the first horizontal extension 121. A first inclined extension 122 extending obliquely toward 20, a second horizontal extension extending in the left and right directions from one end of the first inclined extension 122 and contacted and coupled to the outer surface of the drywall 20. (123), a second inclined extension 124 obliquely extended again from one end of the second horizontal extension 123, and a third horizontal extension again corresponding to the left and right directions from one end of the second inclined extension 124. It may be composed of an extension part 125. Since this has been described above, a more detailed description will be omitted.

Figure 4 is a diagram schematically showing the construction of the drywall stud shown in Figure 3.

Referring to FIG. 4, the stud 100 of this embodiment can be constructed similarly to the existing drywall construction method. Runners 30 are installed up and down, and a plurality of studs 100 may be installed to be spaced left and right between the upper and lower runners 30. In addition, drywall 20, such as gypsum board, may be installed on the inside and outside of the frame formed in this way through studs 100, respectively.

Here, the stud 100 of this embodiment is contact-coupled with the inner drywall 20 to the second horizontal extension 113 of the inner transverse extension 110, and the outer transverse extension 120 on the opposite side. The outer dry wall 20 may be contact-coupled with the second horizontal extension portion 113. In this way, each drywall 20 is supported in contact with the inner and outer transverse extensions 110 and 120 only in the area of the second horizontal extension 113, so the contact area can be reduced and sound insulation performance can be improved.

Figure 5 is a diagram schematically showing a stud for drywall according to a second embodiment of the present invention.

5 and below show other embodiments of the stud 100 described above. The studs 200, 300, and 400 shown in FIG. 5 and below have a generally similar operating principle or purpose to the stud 100 described above, and the explanation below will focus on the differences between the studs 200, 300, and 400 of each embodiment. Let's do it.

Referring to FIG. 5, the stud 200 according to this embodiment may include an inner transverse extension portion 210, an inner and outer connection portion 230, and an outer transverse extension portion 220. This is similar to the stud 100 in the above-described embodiment.

The inner transverse extension portion 210 may be bent and extended from one end of the inner and outer connecting portion 230 to correspond to the left and right directions. Here, the inner transverse extension 210 of this embodiment includes a first horizontal extension 211, a first inclined extension 212 obliquely extending from one end of the first horizontal extension 211, and a first inclined extension. It may be configured as a second horizontal extension portion 213 that extends from one end of the portion 212 to correspond to the left and right directions and is contacted and fastened to the dry wall 20. This is similar to the form in which the second inclined extension part 114 and the third horizontal extension part 115 are omitted in the above-described embodiment.

In the stud 200 of this embodiment, the second inclined extension part 114 and the third horizontal extension part 115 are omitted, so that the inner and outer spacing between the first horizontal extension part 211 and the second horizontal extension part 213 is reduced. is further secured, and the bending angle of the first inclined extension portion 212 can be formed to be relatively large. This allows the sound insulation performance or the effect of acoustic energy dissipation to be improved depending on the installation environment. In this embodiment, the second horizontal extension portion 213 may have a width (W4) of 30 to 50% of the total left and right width (W3) of the inner transverse extension portion (210).

Meanwhile, the outer transverse extension portion 220 may be provided at an end opposite to the inner and outer connection portion 230 to correspond to the inner transverse extension portion 210. In this embodiment, the outer transverse extension portion 220 may have a generally symmetrical structure or shape with the inner transverse extension portion 210.

Figure 6 is a diagram schematically showing a stud for drywall according to a third embodiment of the present invention.

Referring to Figure 6, the stud 300 of the present embodiment may be provided with an inner transverse extension portion 310, an inner and outer connection portion 330, and an outer transverse extension portion 320, which are similar to the previously described embodiments. Similar to

In this embodiment, the inner transverse extension portion 310 sequentially includes a first horizontal extension portion 311, a first inclined extension portion 312, a second horizontal extension portion 313, from the inner and outer connecting portion 330. It may be provided with a second inclined extension part 314 and a third horizontal extension part 315. This is similar to the first embodiment described above. Here, the first inclined extension portion 312 of this embodiment may be formed by bending to form a predetermined acute angle between the first horizontal extension portion 311 and the first inclined extension portion 312 . For example, the first inclined extension portion 312 may be bent so that the included angle A1 with the first horizontal extension portion 311 is 30 to 60 degrees. Also, similarly, the second inclined extension portion 314 may be formed by bending to form a predetermined acute angle between the third horizontal extension portion 315 and the third horizontal extension portion 315 . These first and second inclined extension parts 312 and 314 may be bent to form a symmetrical shape around the second horizontal extension part 313.

Meanwhile, the outer transverse extension portion 320 may be provided at an end opposite to the inner and outer connection portion 330 to correspond to the inner transverse extension portion 310 as described above. Similar to the above-described embodiments, the outer transverse extension portion 320 of the present embodiment may have a generally symmetrical structure or shape with the inner transverse extension portion 310.

Similar to the above-described embodiments, the stud 300 of this embodiment partially contacts the drywall 20 only in the area of the second horizontal extension 313, thereby reducing the transmission of sound pressure due to the sound bridge phenomenon. You can do it. Furthermore, in this embodiment, the first and second inclined extensions 312 and 314 form a predetermined acute angle with the first and second horizontal extensions 311 and 315 and have a more completely bent shape, and vibration is dissipated at this bent area. This allows for more effective sound insulation performance.

Figure 7 is a diagram schematically showing a stud for drywall according to a fourth embodiment of the present invention.

Referring to Figure 7, the stud 400 of this embodiment may be provided with an inner transverse extension part 410, an inner and outer connection part 430, and an outer transverse extension part 420, and the inner and outer transverse extensions. The parts 410 and 420 include a first horizontal extension 411, a first inclined extension 412, a second horizontal extension 413, a second inclined extension 414, and a third horizontal extension ( 415) can be provided. This is generally similar to the first embodiment described above.

Here, the stud 400 of this embodiment may have an inner transverse extension portion 410 and an outer transverse extension portion 420 formed in asymmetrical shapes. That is, according to the example, the second horizontal extension portion 413 of the inner transverse extension portion 410 may have a first width W5 on the left and right, and the second horizontal extension portion 413 of the outer transverse extension portion 420 may have a first width W5. The extension portion 413 may have a second width W6 that is smaller than the first width W5 to the left and right by a predetermined amount.

The asymmetrical stud 400 as described above produces the corresponding sound in each of the inner and outer lateral extensions 410 and 420 according to the noise characteristics of each divided space, the division between indoors and outdoors, and the frequency range of the mainly generated noise. Allows energy to be dissipated more effectively. In some cases, a plurality of asymmetric studs 400 may be arranged on the frame structure so that the inner and outer directions alternate with each other.

As described above, the studs 100 to 400 according to embodiments of the present invention reduce the contact area with the outer surface of the drywall 20 and dissipate acoustic energy through the bent portion, thereby mediating the studs 100 to 400. It is possible to reduce sound pressure transmission and improve the sound insulation performance of the drywall 20.

In addition, despite the above advantages, the studs 100 to 400 according to embodiments of the present invention can be manufactured or processed relatively easily by adding only a predetermined bent shape to the existing stud shape. In addition, the left and right widths of the studs (100 to 400) can be easily manufactured to the same or corresponding specifications as existing studs, so compatibility with existing construction structures and constructability can also be maintained.

Although the embodiments of the present invention have been described above, those skilled in the art will understand that addition, change, deletion or addition of components is possible without departing from the technical spirit of the present invention as set forth in the patent claims. The present invention may be modified or changed in various ways, and this will also be included in the scope of rights of the present invention.

100: stud 110: inner transverse extension
111: first horizontal extension 112: first inclined extension
113: second horizontal extension 114: second inclined extension
115: third horizontal extension 120: outer transverse extension
130: Inner and outer connection part

Claims (7)

It relates to studs (100, 200, 300, 400) that have a predetermined cross-section and extend in the longitudinal direction to provide a support structure for drywall,
Inner and outer connections (130, 230, 330, 430);
An inner transverse extension portion (110, 210, 310, 410) extending from one end of the inner and outer connection portion and fastened to the dry wall on one side; and
It includes an outer transverse extension portion (120, 220, 320, 420) extending from an end opposite the inner and outer connection portion and fastened to the dry wall on the opposite side,
The inner and outer transverse extensions,
A stud for drywall that is formed to enable elastic deformation, has one or more bent portions, and is partially installed in contact with each drywall. In claim 1,
The inner transverse extension 110 is,
A first horizontal extension portion 111 extending in the left and right directions so as to be perpendicular to the inner and outer connecting portions 130;
a first inclined extension portion 112 obliquely extending from an end of the first horizontal extension portion 111;
a second horizontal extension portion 113 extending from an end of the first inclined extension portion 112 in the left and right directions parallel to the first horizontal extension portion 111 and installed in contact with the outer surface of the drywall;
a second inclined extension portion 114 obliquely extending from an end of the second horizontal extension portion 113; and
A stud for drywall including a third horizontal extension portion (115) extending in the left and right directions from an end of the second inclined extension portion (114) to be parallel to the second horizontal extension portion (113). In claim 1,
The inner transverse extension 210 is,
A first horizontal extension portion 211 extending in the left and right directions so as to be perpendicular to the inner and outer connecting portions 230;
a first inclined extension portion 212 extending obliquely from an end of the first horizontal extension portion 211 toward the outer surface of the drywall; and
A second horizontal extension portion 213 extends from the end of the first inclined extension portion 212 in the left and right directions parallel to the first horizontal extension portion 211 and is installed in contact with the outer surface of the drywall. Studs for drywall. In claim 1,
The inner transverse extension 310 is,
A first horizontal extension portion 311 extending from the inner and outer connecting portion 330;
a first inclined extension portion 312 bent and extending from an end of the first horizontal extension portion 311 to form a predetermined acute angle between the first horizontal extension portion 311;
a second horizontal extension portion 313 extending from an end of the first inclined extension portion 312 to be parallel to the first horizontal extension portion 311 and installed in contact with the outer surface of the drywall;
a second inclined extension portion 314 bent and extending from an end of the second horizontal extension portion 313 to correspond to the first inclined extension portion 312; and
A third horizontal extension part ( 315); studs for drywall including; The method of any one of claims 2 to 4,
The outer transverse extension portions 120, 220, 320,
A stud for drywall formed at an end opposite to the inner and outer connecting portions (130, 230, 330) to have a symmetrical shape with the inner transverse extension portions (110, 210, 310). The method of any one of claims 2 to 4,
The inner and outer transverse extensions (110, 120; 210, 220; 310, 3 20),
A stud for drywall extending from the inner and outer connecting portions (130, 320, 33) to have a left and right width (W1, W2) of 40 to 60 mm. The method of any one of claims 2 to 4,
The drywall is,
Studs for drywall, including gypsum board.